Over-write capable magnetooptical recording medium having groove depth of 800 Å or less

ABSTRACT

There is disclosed an over-write capable magnetooptical recording medium, which includes a substrate having spirally or concentrically formed land portions, and grooves formed between the adjacent land portions on its surface, and at least two layers including a memory layer having perpendicular magnetic anisotropy, and a writing layer exchange-coupled to the memory layer, and having perpendicular magnetic anisotropy, the stacking order of these layers not being specifically limited, characterized in that the depth of each of the grooves is set to be 800 Å or less. The groove depth is preferably 300 Å or more for tracking. Within this groove depth range, a C/N ratio can be higher than a case wherein a groove has a depth larger than 800 Å.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to a magnetooptical recording medium, which can perform an over-write operation upon being irradiated with a laser beam, which is pulse-modulated according to binary information to be recorded, without modulating the direction and intensity of a bias field Hb.

An over-write operation means an operation for recording new information without erasing previous information. In this case, when recorded information is reproduced, the previous information must not be reproduced.

2. Related Background Art

In recent years, many efforts have been made to develop an optical recording/reproduction method which can satisfy various requirements including high density, large capacity, high access speed, and high recording/reproduction speed, and a recording apparatus, a reproduction apparatus, and a recording medium used therefor.

Of various optical recording/reproduction methods, the magnetooptical recording/reproduction method is most attractive due to its unique advantages in that information can be erased after it is recorded, and new information can be repetitively recorded.

A recording medium used in the magnetooptical recording/reproduction method has a perpendicular magnetic layer or layers as a recording layer. The magnetic layer comprises, for example, amorphous GdFe or GdCo, GdFeCo, TbFe, TbCo, TbFeCo, and the like. Concentrical or spiral tracks are normally formed on the recording layer, and information is recorded on the tracks. In this specification, one of "upward" and "downward" directions of magnetization with respect to a film surface is defined as an "A direction", and the other one is defined as a "non-A direction". Information to be recorded is binary-coded in advance, and is recorded by two signals, i.e., a bit (B₁) having an "A-directed" magnetization, and a bit (B₀) having a "non-A-directed" magnetization. These bits B₁ and B₀ correspond to "1" and "0" levels of a digital signal. However, in general, the direction of magnetization of the recording tracks can be aligned in the "non-A direction" by applying a strong external field before recording. This "aligning process" is called "initialize*" in a conventional sense. Thereafter, a bit (B₁) having an "A-directed" magnetization is formed on the tracks. Information is expressed in accordance with the presence/absence and/or a bit length of the bit (B₁). Note that a bit is often called a mark recently.

Principle of Bit Formation

In the bit formation, a characteristic feature of laser, i.e., excellent coherence in space and time, is effectively used to focus a beam into a spot as small as the diffraction limit determined by the wavelength of the laser light. The focused light is radiated onto the track surface to record information by producing bits less than 1 μm in diameter on the recording layer. In the optical recording, a recording density up to 10⁸ bits/cm² can be theoretically attained, since a laser beam can be concentrated into a spot with a size as small as its wavelength.

As shown in FIG. 2, in the magnetooptical recording, a laser beam (L) is focused onto a recording layer (1) to heat it, while a bias field (Hb) is externally applied to the heated portion in the direction opposite to the initialized* direction. A coercivity H_(C) of the locally heated portion is decreased below the bias field (Hb). As a result, the direction of magnetization of that portion is aligned in the direction of the bias field (Hb). In this way, reversely magnetized bits are formed.

Ferromagnetic and ferrimagnetic materials differ in the temperature dependencies of the magnetization and H_(C). Ferromagnetic materials have H_(C) which decreases around the Curie temperature and allow information recording based on this phenomenon. Thus, information recording in ferromagnetic materials is referred to as T_(C) recording (Curie temperature recording).

On the other hand, ferrimagnetic materials have a compensation temperature T_(comp)., below the Curie temperature, at which magnetization (M) becomes zero. The H_(C) abruptly increases around this temperature and hence abruptly decreases outside this temperature. The decreased H_(C) is canceled by a relatively weak bias field (Hb). Namely, recording is enabled. This process is called T_(comp). recording (compensation point recording).

In this case, however, there is no need to adhere to the Curie point or temperatures therearound, and the compensation temperature. In other words, if a bias field (Hb) capable of canceling a decreased H_(C) is applied to a magnetic material having the decreased H_(C) at a predetermined temperature higher than a room temperature, recording is enabled.

Principle of Reproduction

FIG. 3 shows the principle of information reproduction based on the magnetooptical effect. Light is an electromagnetic wave with an electromagnetic-field vector normally emanating in all directions in a plane perpendicular to the light path. When light is converted to linearly polarized beams (L_(P)) and irradiated onto a recording layer (1), it is reflected by its surface or passes through the recording layer (1). At this time, the plane of polarization rotates according to the direction of magnetization (M). This phenomenon is called the magnetic Kerr effect or magnetic Faraday effect.

For example, if the plane of polarization of the reflected light rotates through θ_(k) degrees for the "A-directed" magnetization, it rotates through -θ_(k) degrees for the "non-A-directed" magnetization. Therefore, when the axis of an optical analyzer (polarizer) is set perpendicular to the plane inclined at -θ_(k), the light reflected by a "non-A-direction" magnetized bit (B₀) cannot pass through the analyzer. On the contrary, a component corresponding to a product of (sin2θ_(k))² and the light reflected by a bit (B₁) magnetized along the "A direction" passes through the analyzer and becomes incident on a detector (photoelectric conversion means). As a result, the bit (B₁) magnetized along the "A direction" looks brighter than the bit (B₀) magnetized along the "non-Adirection", and causes the detector to produce a stronger electrical signal. The electrical signal from the detector is modulated in accordance with the recorded information, thus reproducing the information.

In order to re-use a recorded medium, (i) the medium must be re-initialized* by an initialize* device, or (ii) an erase head having the same arrangement as a recording head must be added to a recording apparatus, or (iii) as preliminary processing, recorded information must be erased using a recording apparatus or an erasing apparatus.

Therefore, in the conventional magnetooptical recording method, it is impossible to perform an over-write operation, which can properly record new information regardless of the presence/absence of recorded information.

If the direction of a bias field Hb can be desirably modulated between the "A-direction" and "non-A direction", an over-write operation is possible. However, it is impossible to modulate the direction of the bias field Hb at high speed. For example, if the bias field Hb comprises a permanent magnet, the direction of the magnet must be mechanically reversed. However, it is impossible to reverse the direction of the magnet at high speed. Even when the bias field Hb comprises an electromagnet, it is also impossible to modulate the direction of a large-capacity current at high speed.

However, according to remarkable technical developments, a magnetooptical recording method capable of performing an over-write operation by modulating only an intensity of a light beam to be irradiated in accordance with binary coded information to be recorded without modulating a strength (including an ON/OFF state) or the direction of the bias field Hb, an over-write capable magnetooptical recording medium used in this method, and an over-write capable recording apparatus used in this method were invented and filed as a patent application (Japanese Patent Laid-Open Application No. 62-175948 corresponding to DE 3,619 618 and to U.S patent application Ser. No. 453,255). This invention will be quoted as the basic invention hereinafter.

DESCRIPTION OF THE BASIC INVENTION

The basic invention uses an "over-write capable multilayered magnetooptical recording medium which includes a recording layer (to be referred to as a memory layer or M layer hereinafter in this specification) which comprises a perpendicularly magnetizable magnetic thin film, and a reference layer (to be referred to as a "writing layer" or W layer hereinafter in this specification) which comprises a perpendicularly magnetizable magnetic thin film, and in which the two layers are exchange-coupled, and the direction of magnetization of only the W layer can be aligned in a predetermined direction without changing the direction of magnetization of the M layer at a room temperature".

Information is expressed by a bit having an "A-directed" magnetization, and a bit having a "non-A-directed" magnetization in the M layer (in some cases, also in the W layer).

In this medium, the direction of magnetization of the W layer can be aligned in an "A direction" by an external means (e.g., an initial field Hini.). At this time, the direction of magnetization of the M layer is not reversed. Furthermore, the direction of magnetization of the W layer which has been aligned in the "A direction" is not reversed upon application of an exchange coupling force from the M layer. In contrast to this, the direction of magnetization of the M layer is not reversed upon application of an exchange coupling force from the W layer aligned in the "A direction".

The W layer has a lower coercivity H_(C) and a higher Curie temperature T_(C) than those of the M layer.

According to a recording method of the basic invention, only the direction of magnetization of the W layer of the recording medium is aligned in the "A direction" by an external means until a time immediately before recording. This process will be specially referred to as "initialize" in this specification. The "initialize" process is unique to an over-write capable medium.

Thereafter, a laser beam which is pulse-modulated in accordance with binary coded information is irradiated on the medium. The laser beam intensity has high level P_(H) and low level P_(L). These high and low levels correspond to high and low levels of a pulse. Note that low level is higher than very low level* P_(R) to be irradiated on the medium in a reproduction mode. Therefore, for example, an output waveform of a laser beam in the basic invention is as shown in FIG. 4A.

Although not described in the specification of the basic invention, a recording beam need not always be a single beam but may be two proximity beams in the basic invention. More specifically, a leading beam may be used as a low-level laser beam (erasing beam) which is not modulated in principle, and a trailing beam may be used as a high-level laser beam (writing beam) which is modulated in accordance with information. In this case, the trailing beam is pulse-modulated between high level and base level (equal to or lower than low level, and its output may be zero). In this case, an output waveform is as shown in FIG. 4B.

A bias field Hb whose direction and strength are not modulated is applied to a medium portion irradiated with the beam. The bias field Hb cannot be focused to a size as small as the portion irradiated with the beam (spot region), and a region where the bias field Hb is applied is considerably larger than the spot region.

When a low-level beam is radiated, a bit in one of the "A direction" and the "non-A direction" is formed in the M layer regardless of the direction of magnetization of a previous bit.

When a high-level beam is irradiated, a bit in the other direction is formed in the M layer regardless of the direction of magnetization of the previous bit.

Thus, the over-write operation is completed.

In the basic invention, a laser beam is pulse-modulated according to information to be recorded. However, this procedure itself has been performed in the conventional magnetooptical recording method, and a means for pulse-modulating the beam intensity on the basis of binary coded information to be recorded is a known means. For example, see "THE BELL SYSTEM TECHNICAL JOURNAL, Vol. 62 (1983), pp. 1923-1936 for further details. Therefore, the modulating means is available by partially modifying the conventional beam modulating means if required high and low levels of the beam intensity are given. Such a modification would be easy for those who are skilled in the art if high and low levels of the beam intensity are given.

One characteristic feature of the basic invention lies in high and low levels of the beam intensity. More specifically, when the beam intensity is at high level, "A-directed" magnetization of the W layer is reversed to the "non-A direction" by an external means such as a bias field (Hb) and the like, and a bit having the "non-A-directed" [or "A-directed"] magnetization is thus formed in the M layer by means of the "non-A-directed" magnetization of the W layer. When the beam intensity is at low level, the direction of magnetization of the W layer is left unchanged from the initialized state, and a bit having the "A-directed" [or "non-A-directed"] magnetization is formed in the M layer under the influence of the W layer (this influence is exerted on the M layer through the exchange coupling force).

In this specification, if expressions ∘∘∘ [or ΔΔΔ]appear, ∘∘∘ outside the parentheses in the first expression corresponds to ∘∘∘ in the subsequent expressions ∘∘∘ [or ΔΔΔ], and vice versa.

A medium used in the basic invention is roughly classified into first and second categories. In either category, a recording medium has a multilayered structure including the M and W layers.

The M layer is a magnetic layer, which exhibits a high coercivity at a room temperature, and has a low magnetization reversing temperature. The W layer is a magnetic layer, which exhibits a relatively lower coercivity at a room temperature and has a higher magnetization reversing temperature than those of the M layer. Note that each of the M and W layers may comprise a multilayered structure. If necessary, a third layer (e.g., an adjusting layer for an exchange coupling force σ_(w)) may be interposed between the M and W layers. See Japanese Patent Laid-Open Application No. 64-50257 and No. 1-273248. In addition, a clear boundary between the M and W layers need not be formed, and one layer can be gradually converted into the other layer.

In the first category, when the coercivity of the M layer is represented by H_(C1) ; that of the W layer H_(C2) ; a Curie temperature of the M layer, T_(C1) ; that of the W layer, T_(C2) ; a room temperature, T_(R) ; a temperature of the recording medium obtained when a laser beam at low level P_(L) is irradiated, T_(L) ; that obtained when a laser beam at high level P_(H) is irradiated, T_(H) ; a coupling field applied to the M layer H_(D1) ; and a coupling field applied to the W layer, H_(D2), the recording medium satisfies Formula 1 below, and satisfies Formulas 2 to 5 at the room temperature:

    T.sub.R <T.sub.C1 ≈T.sub.L <T.sub.C2 ≈T.sub.H Formula 1

    H.sub.C1 >H.sub.C2 +|H.sub.D1 ∓H.sub.D2 |Formula 2

    H.sub.C1 >H.sub.D1                                         Formula 3

    H.sub.C2 >H.sub.D2                                         Formula 4

    H.sub.C2 +H.sub.D2 <|Hini.|<H.sub.C1 ±H.sub.D1 Formula 5

In the above formulas, symbol "≈" means "equal to" or "substantially equal to (±20°C.)". In addition, of double signs ± and ∓, the upper sign corresponds to an A (antiparallel) type medium, and the lower sign corresponds to a P (parallel) type medium (these media will be described later). Note that a ferromagnetic medium belongs to a P type.

The relationship between a coercivity and a temperature is as shown in the graph of FIG. 6. In FIG. 6, a thin curve represents the characteristics of the M layer, and a bold curve represents those of the W layer.

Therefore, when an external means, e.g., an initial field (Hini.) is applied to this recording medium at the room temperature, the direction of magnetization of only the W layer is reversed without reversing that of the M layer according to Formula 5. When the external means exerts an influence (e.g., the initial field (Hini.)) on the medium before recording, only the direction of magnetization of the W layer can be aligned in the "A direction". That is, the "initialize" process is performed. In the following description, the "A direction" is indicated by an upward arrow in this specification, and the "non-A direction" is indicated by a downward arrow for the sake of simplicity. If the initial field Hini. becomes zero, the direction of magnetization of the W layer can be left unchanged without being re-reversed according to Formula 4.

FIG. 7 schematically shows a state wherein only the W layer is magnetized by the external means in the "A direction" until a time immediately before recording.

In FIG. 7, the direction of magnetization* in the M layer represents previously recorded information. In the following description since the direction of magnetization of the M layer can be disregarded, it is simply indicated by X, as shown in CONDITION 1 in FIG. 7 or 8.

In CONDITION 1, a high-level laser beam is radiated on the medium to increase a medium temperature to T_(H). Since T_(H) is higher than the Curie temperature T_(C1), the magnetization of the M layer disappears. In addition, since T_(H) is near the Curie temperature T_(C2), the magnetization of the W layer also disappears completely or almost completely. The bias field Hb in the "A direction" or "non-A direction" is applied to the medium in accordance with a type of medium. The bias field Hb may be a stray field from the medium itself. For the sake of simplicity, assume that the bias field Hb in the "non-A direction" is applied to the medium. Since the medium is moving, a given irradiated portion is immediately separated apart from the laser beam, and is cooled. When the medium temperature is decreased under the presence of Hb, the direction of magnetization of the W layer is reversed to the "non-A direction" to follow Hb (CONDITION 2 in FIG. 8).

When the medium is further cooled and the medium temperature is decreased slightly below T_(C1), magnetization of the M layer appears again. In this case, the direction of magnetization of the M layer is influenced by that of the W layer through a magnetic coupling (exchange coupling) force, and is aligned in a predetermined direction. As a result, a "non-A-directed" bit (the P type medium) or an "A-directed" bit (the A type medium) is formed according to the type of medium. This state corresponds to CONDITION 3 (P type) or 4 (A type) in FIG. 8.

A change in condition caused by the high-level laser beam will called a high-temperature cycle herein.

A laser beam at low level P_(L) is irradiated on the medium to increase the medium temperature to T_(L). Since T_(L) is near the Curie temperature T_(C1), the magnetization of the M layer disappears completely or almost completely. However, since T_(L) is lower than the Curie temperature T_(C2), the magnetization of the W layer does not disappear. This state is represented by CONDITION 5 in FIG. 8. In this state, although the bias field Hb is unnecessary, it cannot be turned on or off at high speed (within a short period of time). Therefore, the bias field Hb in the high-temperature cycle is left applied inevitably.

However, since the H_(C2) is kept high, the magnetization of the W layer will not be reversed by Hb. Since the medium is moving, a given irradiated portion is immediately separated apart from the laser beam, and is cooled. As cooling progresses, the magnetization of the M layer appears again. The direction of magnetization appearing in this case is influenced by the W layer through the magnetic coupling force, and is aligned in a predetermined direction. As a result, an "A-directed" bit (P type) or a "not-A-directed" bit (A type) is formed in the M layer according to the type of medium. This magnetization is left unchanged at the room temperature. This state corresponds to CONDITION 6 (P type) or 7 (A type) in FIG. 8.

A change in condition caused by the low-level laser beam will be called a low-temperature cycle herein.

As described above, "non-A-directed" and "A-directed" bits can be desirably formed by selecting the high- and low-temperature cycles independently of the direction of magnetization of the M layer before recording. More specifically, an over-write operation is enabled by pulse-modulating the laser beam between high level (high-temperature cycle) and low level (low-temperature cycle) in accordance with information. Refer to FIGS. 9A and 9B. FIGS. 9A and 9B illustrate directions of magnetization of P and A type media at the room temperature or formed when the medium temperature is returned to the room temperature.

In the above description, both the first and W layers have no compensation temperature T_(comp). between the room temperature and the Curie temperature. However, when the compensation temperature T_(comp). is present, if the medium temperature exceeds it, 1 the direction of magnetization is reversed (in practice, although the directions of sublattice magnetization of RE and TM atoms are not changed, since the relationship between their strengths is reversed, the direction of magnetization of the alloy is reversed), and 2 A and P types are reversed. For these reasons, a description must be complicated accordingly. In this case, the direction of the bias field Hb is opposite to the direction ↓ in the above description at the room temperature. That is, Hb in the same direction as the "initialized" direction ↑ of magnetization of the W layer is applied.

A recording medium normally has a disk shape, and is rotated during recording. For this reason, a recorded portion (bit) is influenced again by an external means, e.g., Hini. after recording. As a result, the direction of magnetization of the W layer is aligned in the original "A direction" . In other words, the W layer is "initialized". However, at the room temperature, the magnetization of the W layer can no longer influence that of the M layer, and the recorded information can be held.

If linearly polarized light is irradiated on the M layer, since light reflected thereby includes information, the information can be reproduced as in the conventional magnetooptical recording medium.

A perpendicular magnetic film constituting each of the M and W layers is selected from the group consisting of 1 amorphous or crystalline ferromagnetic and ferrimagnetic materials having no compensation temperature and having a Curie temperature, and 2 an amorphous or crystalline ferrimagnetic material having both the compensation temperature and the Curie temperature.

The first category which utilizes the Curie temperature as the magnetization reversing temperature has been described. In contrast to this, the second category utilizes H_(C) decreased at a temperature lower than the Curie temperature. In the second category, substantially the same description as the first category can be applied except that a temperature T_(S1) at which the M layer is magnetically coupled to the W layer is used in place of T_(C1) in the first category, and a temperature T_(S2) at which the direction of magnetization of the W layer is reversed by Hb is used in place of T_(C2).

In the second category, when the coercivity of the M layer is represented by H_(C1) ; that of the W layer, H_(C2) ; a temperature at which the M layer is magnetically coupled to the W layer, T_(S1) ; a temperature at which the magnetization of the W layer is reversed by Hb, T_(S2) ; a room temperature, T_(R) ; a medium temperature obtained when a laser beam at low level P_(L) is irradiated, T_(L) ; that obtained when a laser beam at high level P_(H) is irradiated, T_(H) ; a coupling field applied to the M layer, H_(D1) ; and a coupling field applied to the W layer H_(D2), the recording medium satisfies Formula 6 below, and satisfies Formulas 7 to 10 at the room temperature:

    T.sub.R <T.sub.S1 ≈T.sub.L <T.sub.S2 ≈T.sub.H Formula 6

    H.sub.C1>H.sub.C2 +|H.sub.D1 ∓H.sub.D2 |Formula 7

    H.sub.C1 >H.sub.D1                                         Formula 8

    H.sub.C2 >H.sub.D2                                         Formula 9

    H.sub.C2 +H.sub.D2 <|Hini.|<H.sub.C1 ±H.sub.D1 Formula 10

In the above formulas, of double signs ± and ∓, the upper sign corresponds to an A (antiparallel) type medium, and the lower sign corresponds to a P (parallel) type medium (these media will be described later).

In the second category, when the medium is at the high temperature T_(H), the magnetization of the W layer does not disappear, but is sufficiently weak. The magnetization of the M layer disappears, or is sufficiently weak. Even if sufficiently weak magnetization is left in both the M and W layers, the bias field Hb ↓ is sufficiently large, and the Hb ↓ forces the direction of magnetization of the W layer and that of the M layer in some cases to follow that of the Hb ↓. This state corresponds to CONDITION 2 in FIG. 10.

Thereafter, the W layer influences the M layer via σ_(w) 1 immediately, or 2 when cooling progresses after irradiation of the laser beam is stopped and the medium temperature is decreased below T_(H), or 3 when the irradiated portion is away from Hb, thereby aligning the direction of magnetization of the M layer in a stable direction. As a result, CONDITION 3 (P type) or 4 (A type) in FIG. 10 is established.

On the other hand, when the medium is at the low temperature T_(L), both the W and M layers do not lose their magnetization. However, the magnetization of the M layer is relatively weak. In this case, there are two bit states, i.e., CONDITIONs 5 and 6 in FIG. 10 for P type, and there are also two bit states, i.e., CONDITIONs 7 and 8 in FIG. 10 for A type. In CONDITIONs 6 and 8, a magnetic wall (indicated by a bold line) is generated between the M and W layers, and the medium is in a relatively unstable (metastable) condition. The medium portion in this condition is applied with Hb ↓ immediately before it reaches the irradiation position of the laser beam. Nevertheless, CONDITION 6 or 8 can be maintained. Because, since the W layer has sufficient magnetization at the room temperature, the direction of magnetization of the W layer will not be reversed by Hb ↓. The M layer in CONDITION 8, whose direction of magnetization is opposite to Hb ↓, receives the influence of the exchange coupling force σ_(w) larger than the influence of Hb ↓, and the direction of magnetization of the M layer is held in the same direction as that of the W layer since the medium is of P type.

Thereafter, the portion in CONDITION 6 or 8 is irradiated with a low-level laser beam. For this , reason, the medium temperature is increased. Upon an increase in medium temperature, the coercivities of the two layers are decreased. However, since the W layer has a high Curie temperature, a decrease in coercivity H_(C2) is small, and the "A direction" corresponding to 20 the "initialized" direction of magnetization is maintained without being overcome with Hb ↓. On the other hand, since the medium temperature is lower than the Curie temperature T_(C1) of the M layer although the M layer has the low Curie temperature, the coercivity H_(C1) remains. However, since the coercivity H_(C1) is small, the M layer receives 1 the influence of Hb ↓ and 2 the influence via the exchange coupling force σ_(w) from the W layer (force for aligning the direction of magnetization of the M layer in the same direction as that of the W layer in P type). In this case, the latter influence is stronger than the former influence, and the following formulas are simultaneously satisfied: ##EQU1## The lowest temperature at which these formulas are simultaneously satisfied will be called T_(LS). In other words, the lowest temperature at which the magnetic wall in CONDITION 6 or 8 disappears is T_(LS).

As a result, CONDITION 6 transits to CONDITION 9, and CONDITION 8 transits to CONDITION 10. On the other hand, CONDITION 5 originally having no magnetic wall is the same as CONDITION 9, and CONDITION 7 is the same as CONDITION 10. Consequently, a bit in CONDITION 9 (P type) or 10 (A type) is formed upon irradiation of the low-level beam regardless of the previous state (CONDITION 5 or 6 for P type, or CONDITION 7 or 8 for A type).

This state is maintained when the medium temperature is decreased to the room temperature after the laser beam irradiation is stopped or the bit falls outside the irradiation position. CONDITION 9 (P type) or 10 (A type) in FIG. 10 is the same as CONDITION 6 (P type) or 7 (A type) in FIG. 8.

As can be understood from the above description, the low-temperature cycle is executed without increasing the medium temperature up to the Curie temperature T_(C1) of the M layer.

Even when the low-temperature cycle is executed at a temperature equal to or higher than T_(C1), since the medium temperature is increased from the room temperature to T_(C1) via T_(LS), CONDITION 6 transits to CONDITION 9 for P type, and CONDITION 8 transits to CONDITION 10 for A type at that time. Thereafter, the medium temperature reaches T_(C1), and CONDITION 5 shown in FIG. 8 is established.

In the above description, both the M and W layers have no compensation temperature T_(comp). between the room temperature and the Curie temperature. However, when the compensation temperature T_(comp). is present, if the medium temperature exceeds it, 1 the direction of magnetization is reversed, and 2 A and P types are reversed. For these reasons, a description must be complicated accordingly. In this case, the direction of the bias field Hb is opposite to the direction in the above description at the room temperature.

In both the first and second categories, the recording medium is preferably constituted by the M and W layers each of which comprises an amorphous ferrimagnetic material selected from transition metal (e.g., Fe, Co)--heavy rare earth metal (e.g., Gd, Tb, Dy, and the like) alloy compositions.

When the materials of both the M and W layers are selected from the transition metal-heavy rare earth metal alloy compositions, the direction and level of magnetization appearing outside the alloys are determined by the relationship between the direction and level of sublattice magnetization of transition metal (TM) atoms, and those of heavy rare earth metal (RE) atoms inside the alloys. For example, the direction and level of TM sublattice magnetization are represented by a vector indicated by a dotted arrow , those of RE sublattice magnetization are represented by a vector indicated by a solid arrow ↑, and the direction and level of magnetization of the entire alloy are represented by a vector indicated by a hollow arrow . In this case, the hollow arrow (vector) is expressed as a sum of the dotted and solid arrows (vectors). However, in the alloy, the dotted and solid arrows (vectors) are directed in the opposite directions due to the mutual effect of the TM sublattice magnetization and the RE sublattice magnetization. Therefore, when strengths of these magnetizations are equal to each other, the sum of the dotted and solid arrows (vectors), i.e., the vector of the alloy is zero (i.e., the level of magnetization appearing outside the alloy becomes zero). The alloy composition making the vector of the alloy zero is called a compensation composition. When the alloy has another composition, it has a strength equal to a difference between the strengths of the two sublattice magnetizations, and has a hollow arrow (vector or ) having a direction equal to that of the larger vector. Thus, a magnetization vector of the alloy is expressed by illustrating dotted and solid vectors adjacent to each other, as shown in, e.g., FIG. 11. The RE and TM sublattice magnetization states of the alloy can be roughly classified into four states, as shown in FIGS. 12(1A) to 12(4A). Magnetization vectors (hollow arrow or ) of the alloy in the respective states are shown in FIGS. 12(1B) to 12(4B). For example, the alloy in the sublattice magnetization state shown in FIG 12(1A) has a magnetization vector shown in FIG. 12(1B).

When one of the strengths of the RE and TM vectors is larger than the other, the alloy composition is referred to as "∘∘ rich" named after the larger vector (e.g., RE rich).

Both the M and W layers can be classified into TM rich and RE rich compositions. Therefore, when the composition of the M layer is plotted along the ordinate and that of the W layer is plotted along the abscissa, the types of medium as a whole of the basic invention can be classified into four quadrants, as shown in FIG. 13. In FIG. 13, the intersection of the abscissa and the ordinate represents the compensation composition of the two layers.

The P type medium described above belongs to Quadrants I and III in FIG. 13, and the A type-medium belongs to Quadrants II and IV.

In view of a change in coercivity against a change in temperature, a given alloy composition has characteristics wherein the coercivity temporarily increases infinitely and then abruptly decreases before a temperature reaches the Curie temperature (at which the coercivity is zero). The temperature corresponding to the infinite coercivity is called a compensation temperature (T_(comp).). At a temperature lower than the compensation temperature, the RE vector (solid arrow) is larger than the TM vector (dotted arrow) (i.e., TM rich), and vice versa at a temperature higher than the compensation temperature. Therefore, the compensation temperature of the alloy having the compensation composition is assumed to be present at the room temperature.

In contrast to this, no compensation temperature is present between the room temperature and the Curie temperature in the TM rich alloy composition. The compensation temperature below the room temperature is nonsense in the magnetooptical recording, and hence, it is assumed in this specification that the compensation temperature is present between the room temperature and the Curie temperature.

If the M and W layers are classified in view of the presence/absence of the compensation temperature, the medium can be classified into four types. A medium in Quadrant I includes all the four types of media. When both the M and W layers are classified in view of their RE or TM rich characteristics and in view of the presence/absence of the compensation temperature, recording media can be classified into the following nine classes.

                  TABLE 1                                                          ______________________________________                                         Class                       Type                                               ______________________________________                                         Quadrant I (P type)                                                            M layer:           W layer:                                                    RE Rich            RE Rich                                                     ______________________________________                                         1       T.sub.comp.    T.sub.comp.                                                                             1                                              2       No T.sub.comp. T.sub.comp.                                                                             2                                              3       T.sub.comp.    No T.sub.comp.                                                                          3                                              4       No T.sub.comp. No T.sub.comp.                                                                          4                                              Quadrant II (A type)                                                           M layer:           W layer:                                                    RE Rich            TM Rich                                                     ______________________________________                                         5       T.sub.comp.    No T.sub.comp.                                                                          3                                              6       No T.sub.comp. No T.sub.comp.                                                                          4                                              Quadrant III (P type)                                                          M layer:           W layer:                                                    TM Rich            TM Rich                                                     ______________________________________                                         7       No T.sub.comp. No T.sub.comp.                                                                          4                                              Quadrant IV (A type)                                                           M layer:           W layer:                                                    TM Rich            TM Rich                                                     ______________________________________                                         8       No T.sub.comp. T.sub.comp.                                                                             2                                              9       No T.sub.comp. No T.sub.comp.                                                                          4                                              ______________________________________                                    

Description of Class 1-1

The principle of the over-write operation will be described in detail below using a medium No. 1-1 belonging to a recording medium of Class 1 (P type, Quadrant I, and Type 1) shown in Table 1.

This medium No. 1-1 has the relations given by Formula 11:

    T.sub.R <T.sub.comp.1 <T.sub.L <T.sub.H ≦T.sub.C1 ≦T.sub.C2

and, Formula 11-2:

    T.sub.comp.2 <T.sub.C1

In this specification, "=" of "≦" means "equal to" or "almost equal to" (about ±20° C.). For the sake of simplicity, a medium having a relation given by T_(H) <T_(C1) <T_(C2) will be explained below. T_(comp).2 may be high than, equal to, or lower than T_(L). However, for the sake of simplicity, T_(L) <T_(comp).2. The above relations can be expressed by a graph shown in FIG. 14. Note that a thin curve represents the graph of an M layer, and a bold curve represents the graph of a W layer.

A condition that reverses only the direction of magnetization of the W layer by Hini. at room temperature T_(R) without reversing that of the M layer is represented by Formula 12. This medium No. 1-1 satisfies Formula 12: ##EQU2## where H_(C1) :coercivity of M layer

H_(C2) :coercivity of W layer

M_(S1) :saturation magnetization of M layer

M_(S2) :saturation magnetization of W layer

t₁ :film thickness of M layer

t₂ :film thickness of W layer

σ_(w) :exchange coupling force=interface wall energy

At this time, a condition for Hini. is represented by Formula 15. If Hini. disappears, the directions of magnetization of the M and W layers influence each other through an exchange coupling force. The conditions that can hold the directions of magnetization of the M and W layers without reversing them are represented by Formulas 13 and 14. The medium No. 1-1 satisfies Formulas 13 and 14: ##EQU3##

The direction of magnetization of the W layer of the recording medium, which satisfies conditions given by Formulas 12 to 14 at room temperature, is oriented in, e.g., the "A direction" ↑ by Hini. which satisfies Formula 15 before a time immediately before recording: ##EQU4## At this time, the M layer is left in the recorded state. This condition corresponds to either CONDITION 1 or 2 in FIG. 15. CONDITION 1 or 2 is held until a time immediately before recording. Note that the bias field Hb is assumed to be applied in the "A direction" ↑.

Note that it is difficult to focus the bias field Hb to the same range as a region to be irradiated (spot region) of a laser beam as with normal magnetic fields. When a medium has a disk shape, recorded information (bit) is influenced by Hini. during one revolution of the medium, and is set in CONDITION 1 or 2 again. Thereafter, the bit passes a portion near the region to be irradiated (spot region) of the laser beam. At this time, the bit in CONDITION 1 or 2 is influenced by a bias field Hb apply means since it approaches the bias field Hb apply means. In this case, if the direction of magnetization of the M layer of the bit in CONDITION 2 having the direction of magnetization opposite to that of Hb is reversed by Hb, information recorded one revolution before is undesirably erased. A condition for preventing this is given by Formula 15-2: ##EQU5## The disk-shaped medium No. 1-1 must satisfy Formula 15-2 at room temperature. In other words, one condition for determining Hb is given by Formula 15-2.

The bit in CONDITION 1 or 2 then reaches the spot region of the laser beam. The laser beam intensity has two levels, i.e., high and low levels like in the basic invention.

Low-temperature Cycle

Upon irradiation with a low-level laser beam, the medium temperature is increased beyond T_(comp).1. The medium type is then shifted from P type to A type. The relationship between the strengths of RE and TM spins of the M layer is reversed from FIG. 12(3A) to FIG. 12(4A) although the directions of the spins are left unchanged. For this reason, the direction of magnetization of the M layer is reversed from FIG. 12(3B) to FIG. 12(4B). As a result, the bit in CONDITION 1 in FIG. 15 transits to CONDITION 3, or the bit in CONDITION 2 transits to CONDITION 4.

The medium continues to be irradiated with the laser beam, and the medium temperature then reaches T_(L). In this state, Formula 15-3 is satisfied: ##EQU6## As a result, even when Hb ↑ is present, the bit in CONDITION 4 in FIG. 15 transits to CONDITION 5. On the other hand, the bit in CONDITION 3 in FIG. 15 is maintained since Formula 15-3 is satisfied even when Hb ↑ is present. More specifically, CONDITION 3 merely transits to the same CONDITION 5 as CONDITION 3.

In this state, when the bit falls outside the spot region of the laser beam, the medium temperature begins to fall. When the medium temperature is decreased below T_(comp).1, the medium type is restored from A type to original P type. The relationship between the strengths of RE and TM spins of the M layer is reversed from FIG. 12(2A) to FIG. 12(1A). For this reason, the direction of magnetization of the M layer is reversed from FIG. 12(2B) to FIG. 12(1B). As a result, the bit in CONDITION 5 transits to CONDITION 6 (the direction of magnetization of the M layer is oriented in the "A direction" ↑). CONDITION 6 is maintained even when the medium temperature is decreased to room temperature. In this manner, the bit in the "A direction" ↑ is formed in the M layer.

High-temperature Cycle

Upon irradiation with a high-level laser beam, the medium temperature is increased up to the low temperature T_(L) via T_(comp).1. As a result, the same CONDITION 7 as CONDITION 5 in FIG. 15 is established.

Since the medium is irradiated with the high-level laser beam, the medium temperature is further increased. When the medium temperature exceeds T_(comp).2 of the W layer, the medium type is shifted from A type to P type. The relationship between the strengths of RE and TM spins of the W layer is reversed from FIG. 12(1A) to FIG. 12(2A) although the directions of the spins are left unchanged. For this reason, the direction of magnetization of the W layer is reversed from FIG. 12(1B) to FIG. 12(2B). As a result, the direction of magnetization of the W layer is oriented in the "non-A direction" ↓. This condition is CONDITION 8 in FIG. 15.

However, since H_(C2) is still large at this temperature, the direction of magnetization of the W layer will not be reversed by ↑ Hb. When the temperature is further increased and reaches T_(H), the coercivities of the M and W layers are decreased since their temperatures are close to the Curie temperature. As a result, the medium satisfies two formulas in one of the following conditions (1) to (3): ##EQU7##

For this reason, the directions of magnetization of the two layers are reversed at almost the same time, and follow the direction of Hb ↑. This condition corresponds to CONDITION 9 in FIG. 15.

When the bit falls outside the spot region of the laser beam, the medium temperature begins to fall. When the medium temperature is decreased below T_(comp).2, the medium type is shifted from P type to A type. The relationship between the strengths of TM and RE spins is reversed from FIG. 12(4A) to FIG. 12(3A) although the directions of the spins are left unchanged. For this reason, the direction of magnetization of the W layer is reversed from FIG. 12(4B) to FIG. 12(3B). As a result, the direction of magnetization of the W layer is oriented in the "non-A direction" ↓. This condition is CONDITION 10 in FIG. 15. In CONDITION 10, the medium satisfies Formula 15-4: ##EQU8## For this reason, the direction of magnetization of the W layer will not be reversed even when Hb ↑ is applied to the W layer.

When the medium temperature is further decreased from the temperature in CONDITION 10 to a temperature below T_(comp).1, the medium type is restored from A type to original P type. The relationship between the strengths of RE and TM spins of the M layer is reversed from FIG. 12(4A) to FIG. 12(3A). For this reason, the direction of magnetization of the M layer is reversed from FIG. 12(4B) to FIG. 12(3B). As a result, the direction of magnetization of the M layer is oriented in the "non-A-direction" ↓. This condition is CONDITION 11 in FIG. 15.

The medium temperature is then decreased from the temperature in CONDITION 11 to room temperature. Since H_(C1) at room temperature is sufficiently large (see Formula 15-5), the direction of magnetization ↓ of the M layer will not be reversed by ↑ Hb, and CONDITION 11 is maintained. ##EQU9##

In this manner, the bit in the "non-A direction" ↓ is formed in the M layer.

Description of Selection Invention

In the above description, a two-layered film consisting of the M and W layers has been exemplified. An over-write operation is enabled even in a medium including a multi-layered film consisting of three or more layers as long as the medium has the above-mentioned two-layered film. In particular, in the above description, the initial field Hini. is used as the external means. However, in the basic invention, any other external means may be employed. That is, the direction of magnetization of the W layer need only be aligned in a predetermined direction before a time immediately before recording.

For this reason, a structure using, as an external means, an exchange coupling force from an initializing layer in place of Hini. was invented (Japanese Journal "OPTRONICS", 1990, No. 4, pp. 227-231; International Application Laid-Open WO 90/02400 for further details). This invention will be referred to as an alternative invention hereinafter. The selection invention will be described below.

FIG. 16 shows a structure of a medium according to the alternative invention. This medium comprises a substrate and a magnetic film formed on the substrate. The magnetic film has a four layered structure constituted by sequentially stacking an M layer 1 consisting of a perpendicularly magnetizable magnetic thin film, a W layer 2 consisting of a perpendicularly magnetizable magnetic thin film, a switching layer (to be referred to as an S layer hereinafter; also referred to as a control layer in the above-mentioned journal "OPTRONICS") 3 consisting of a perpendicularly magnetizable magnetic thin film, and an initializing layer (to be referred to as an I layer hereinafter) 4 consisting of a perpendicularly magnetizable magnetic thin film (in some cases, the S layer 3 may be omitted). The M and W layers are exchange-coupled to each other, and the direction of magnetization of only the W layer can be aligned in a predetermined direction without changing the direction of magnetization of the M layer at a room temperature. In addition, the W and I layers are exchange-coupled to each other via the S layer at a temperature equal to or lower than a Curie temperature of the S layer.

The I layer has a highest Curie temperature, and does not lose its magnetization upon radiation of a high-level laser beam. The I layer always holds magnetization in a predetermined direction, and serves as means for repetitively "initializing" the W layer to prepare for the next recording every time recording is performed. For this reason, the I layer is called the initializing layer.

However, in a process of a high-temperature cycle (e.g., near T_(H)), the magnetization of the W layer must be reversed. In this case, the influence from the I layer must become negligibly small. When the temperature is increased, an exchange coupling force σ_(w24) between the W and I layers can be conveniently decreased.

However, when sufficient σ_(w24) remains even at T_(H), the S layer is required between the W and I layers. If the S layer consists of a non-magnetic member, σ_(w24) can be reduced to zero or can become very small. However, σ_(w24) must be large enough to "initialize" the W layer at a certain temperature between T_(H) and the room temperature. In this case, the S layer must apply an apparently sufficient exchange coupling force between the W and I layers. For this purpose, the S layer must consist of a magnetic member. Therefore, the S layer is converted to a magnetic member at a relatively low temperature to apply an apparently sufficient exchange coupling force σ_(w24) between the W and I layers, and is converted to a non-magnetic member at a relatively high temperature to apply a zero or very small exchange coupling force σ_(w24) between the W and I layers. For this reason, the S layer is called the switching layer.

The principle of a four-layered film over-write operation will be described below with reference to FIG. 13. A typical example will be described below, but there are some examples in addition to this example. A hollow arrow indicates a direction of magnetization of each layer.

A condition before recording corresponds to either CONDITION 1 or CONDITION 2. Paying attention to an M layer, in CONDITION 1, an "A-directed" bit (B₁) is formed, or in CONDITION 2, a "non-A-directed" bit (B₀) is formed, a magnetic wall (indicated by a bold line) is present between the M layer and a W layer, and the medium is in a relatively unstable (metastable) state.

Low-Temperature Cycle

A laser beam is irradiated on the bit in CONDITION 1 or 2 to increase a temperature. First, magnetization of an S layer disappears. For this reason, CONDITION 1 transits to CONDITION 3, or CONDITION 2 transits to CONDITION 4.

When the temperature is further increased, and reaches T_(LS), the magnetization of the M layer is weakened, and the influence from the W layer via an exchange coupling force is strengthened. As a result, the direction of magnetization of the M layer in CONDITION 4 is reversed, and at the same time, the magnetic wall between the two layers disappears. This condition corresponds to CONDITION 5. The bit in CONDITION 3 originally has no magnetic wall between the two layers, and directly transits to CONDITION 5.

When irradiation of the laser beam is stopped or an irradiated portion is separated from the irradiation position, the temperature of the bit in CONDITION 5 begins to fall, and CONDITION 1 is then established via CONDITION 3.

This is the low-temperature cycle.

When the temperature is further increased from that in CONDITION 5, and exceeds the Curie temperature of the M layer, magnetization disappears, and CONDITION 6 is established. When irradiation of the laser beam is stopped or an irradiated portion is separated from the irradiation position, the temperature of the bit in CONDITION 6 begins to fall, and then reaches a temperature slightly lower than the Curie temperature of the M layer. Thus, magnetization appears in the M layer. In this case, the direction of magnetization of the M layer is influenced by the W layer via the exchange coupling force, and is aligned in a stable direction with respect to the direction of magnetization of the W layer (i.e., in a direction not to form a magnetic wall between the layers). Since the medium is of P type, CONDITION 5 is reproduced. The temperature is further decreased, and CONDITION 3 is established accordingly. Thereafter, a bit in CONDITION 1 is formed. This process is another example of the low-temperature cycle.

High-Temperature Cycle

When a laser beam is irradiated on the bit in CONDITION 1 or 2 to increase a temperature, CONDITION 6 is established via CONDITION 5, as described above.

When the temperature is further increased, the coercivity of the W layer is decreased considerably. For this reason, the direction of magnetization of the W layer is reversed by a bias field Hb ↓. This is CONDITION 8.

When irradiation of the laser beam is stopped or an irradiated portion is separated from the irradiation position, the medium temperature begins to fall. The medium temperature then reaches a temperature slightly lower than the Curie temperature of the M layer. Thus, magnetization appears in the M layer. The direction of magnetization of the M layer is influenced by the W layer via the exchange coupling force, and is aligned in a stable direction with respect to the direction of magnetization of the W layer (i.e., in a direction not to form a magnetic wall between the layers). Since the medium is of P type, CONDITION 9 appears.

When the temperature is further decreased, magnetization appears in the S layer. As a result, the W layer and an I layer are magnetically coupled (by the exchange coupling force). As a result, the direction of magnetization of the W layer is aligned in a stable direction with respect to the direction of magnetization of the I layer (i.e., in a direction not to form a magnetic wall between the layers). Since the medium is of P type, the direction of magnetization of the W layer is reversed to the "A direction", and as a result, an interface wall is formed between the M and W layers. This condition is maintained at the room temperature, and a bit in CONDITION 2 is formed.

This is the high-temperature cycle.

When the temperature is further increased after CONDITION 8 appears by the bias field Hb ↓, the temperature then exceeds the Curie temperature of the W layer. As a result, CONDITION 7 appears.

When irradiation of the laser beam is stopped or an irradiated portion is separated from the irradiation position, the medium temperature begins to fall. The medium temperature then reaches a temperature slightly lower than the Curie temperature of the W layer. Thus, magnetization appears in the W layer. The direction of magnetization of the W layer follows the direction of the bias field Hb ↓. As a result, CONDITION 8 appears.

When the temperature is further decreased, a bit in CONDITION 2 is formed via CONDITION 9. This process is another example of the high-temperature cycle.

Over-write Operation

As described above, a bit (B₁) in CONDITION 1 is formed in the low-temperature cycle, and a bit (B₀) in CONDITION 2 is formed in the high-temperature cycle independently of a previous recording state. Therefore, an over-write operation is enabled.

PROBLEMS TO BE SOLVED BY THE INVENTION

A magnetooptical recording medium has a disk shape. When the disk is viewed from a direction perpendicular to the disk plane, spiral or concentric tracks for recording information are formed on the disk. Grooves for tracking and separation are present between adjacent tracks. Contrary to this, a portion between adjacent grooves is called a land. In practice, the lands and grooves cannot be identified depending on whether the disk is viewed from the front or back surface side. Thus, when the disk is viewed from a direction of incidence of a beam, as shown in FIG. 17, a portion on the near side is called a groove, and a portion on the far side is called a land. The groove portion may be used as a track, or the land portion may be used as a track. The widths of the groove and the land do not have a particular relationship therebetween.

In order to constitute the lands and grooves, spirally or concentrically formed lands and grooves formed between adjacent land portions are present on the surface of a substrate.

The present inventor manufactured media by variously changing the depth of grooves (in other words, the height of lands), and tried over-write and reproduction operations. The present inventor found that some media had a low C/N ratio (first problem). On the other hand, the initial field Hini. is restricted by Formula 15 in, e.g., the medium No. 1-1. In this case, a recording apparatus requires small Hini. as much as possible. For example, if a small magnetic field equal to or lower than 2 kOe is used, a magnet as an Hini. apply means can be rendered compact, and the recording apparatus can also have a compact structure. When small Hini. was used, a problem of a low C/N ratio (second problem) was conspicuous. In the worst case, recorded information could not be normally reproduced, and an error occurred. In general, the total film thickness of the M and W layers is 500 to 3,000 Å. When the film thickness near the lower limit (500 to 900 Å) was selected so as to improve recording sensitivity, a problem of a low C/N ratio (third problem) was conspicuous.

SUMMARY OF THE INVENTION

Object of the invention is to solve above-mentioned problems.

The present inventor made extensive studies, and found that the depth of the groove and the first to third problems had a causal relationship therebetween. Thus, the present inventor found that the first to third problems could be solved when the depth of the groove was set to be 800 Å or less, and achieved the present invention.

Therefore, the present invention provides an over-write capable magnetooptical recording medium, which includes a substrate having spirally or concentrically formed lands, and grooves formed between the adjacent lands on a surface thereof, and at least two layers including a memory layer having perpendicular magnetic anisotropy, and a writing layer exchange-coupled to the memory layer, and having perpendicular magnetic anisotropy, the stacking order of the layers on the substrate not being specifically limited, characterized in that a depth of each of the grooves is set to be not more than 800 Å.

The reason why the problem of the low C/N ratio can be solved when the depth of the groove is set to be 800 Å or less is not clearly understood. However, it is considered that when the depth of the groove exceeds 800 Å, previous information is slightly left (an unerased portion is left), and decreases the C/N ratio.

Note that since too shallow a groove makes tracking difficult, the depth of the groove is preferably 300 Å or more.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a sectional view showing a sectional structure of an over-write capable magnetooptical recording medium according to an embodiment of the present invention;

FIG. 2 is a schematic view for explaining the principle of recording of a magnetooptical recording method;

FIG. 3 is a schematic view for explaining the principle of reproduction of the magnetooptical recording method;

FIG. 4 is a waveform chart of a laser beam when an overwrite operation is performed according to the basic invention;

FIG. 5 is a weveform chart of a laser beam when an overwrite operation is performed using two beams according to the basic invention;

FIG. 6 is a graph showing the relationship between a coercivity and a temperature of first and second layers of an overwrite-capable magnetooptical recording medium;

FIG. 7 is a schematic view showing directions of magnetization of the first and second layers;

FIG. 8 is a diagram showing changes in direction of magnetization of the first and second layers;

FIGS. 9A and 9B are respectively diagrams showing changes in direction of magnetization of the first and second layers of P and A type media after the low- and high-temperature cycles, and show conditions at a room temperature;

FIG. 10 is a diagram showing changes in direction of magnetization of the first and second layers;

FIG. 11 is an explanatory view for comparing a vector (solid arrow) representing a sublattice magnetization of a rare-earth (RE) atom, and a vector (dotted arrow) representing a sublattice magnetization of a transition-metal (TM) atom;

FIGS. 12(1A) to (4B) are explanatory views showing the relationship between the sublattice magnetization vectors and and a hollow arrow indicating the direction of magnetization of an alloy;

FIG. 13 is a map showing types of media classified into four quadrants;

FIG. 14 is a graph showing the relationship between the coercivities and the temperatures of M and W layers of an over-write capable magnetooptical recording medium No. 1-1;

FIG. 15 is a chart showing changes in directions of magnetization of the M and W layers as a result of low- and high-temperature cycles of the medium No. 1-1;

FIG. 16 is a chart for explaining the over-write principle of a four-layered structure over-write capable magnetooptical recording medium according to the selection invention;

FIG. 17 is a sectional view showing a vertical section of a 2P substrate;

FIG. 18 is an explanatory view for explaining the dimensions of a groove; and

FIG. 19 is a graph showing the relationship between the depth of the groove and a C/N ratio.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

The present invention will be described in detail below by way of its example. However, the present invention is not limited to this.

EXAMPLE: Medium No. 1-1 of Class 1 (P type, Quadrant I, Type 1)

(1) As shown in FIG. 18, a width W of a groove is defined as the quotient obtained by dividing the sum of a width Wb at the bottom of the groove and a width Wt at the top portion (opening portion) of the groove with 2.

Seven different stampers having a width W of the groove of 0.5 μm, a pitch of 1.6 μm, and different heights h ranging between 400 Å and 1,000 Å in 100-Å steps were prepared. A large number of grooves were concentrically formed between a position corresponding to the outer diameter of 200 mm and a position corresponding to the inner diameter of 100 mm.

An ultraviolet setting resin (groove material) was filled in each of these stampers, and a glass substrate G was pressed against the resin. The resin was irradiated with ultraviolet rays through the substrate G to be set. The set resin PP was peeled from the stamper together with the glass substrate G (the set resin PP was firmly adhered to the substrate G). In this manner, seven 2P substrates (SS) having different groove depths h were obtained. FIG. 17 shows a section of the 2P substrate (SS).

(2) A three-element RF sputtering apparatus was prepared, and the above 2P substrate was set in a chamber of the apparatus. The interior of the chamber of the apparatus was temporarily evacuated to a vacuum of 7×10⁻⁷ Torr or less, and thereafter, Ar gas was introduced to 5×10 Torr. Then, sputtering was performed at a deposition rate of about 2 Å/sec.

First, an Al target was used as a first target, and N₂ gas was introduced into the chamber in addition to the Ar gas. Reactive sputtering was then performed to form a 700-Å thick aluminum nitride film (first protection layer R) on the resin.

The N₂ gas introduction was stopped, and sputtering was performed using a TbFeCo alloy as a second target in the Ar gas at 5×10 Torr. In this manner, an M layer comprising a Tb₂₃ Fe₇₂ Co₅ (suffixes are in units of atomic %; the same applies to the following description) perpendicularly magnetizable magnetic film having a film thickness t₁ =300 Å was formed on the first protection layer.

Subsequently, simultaneous sputtering was performed using a DyFeCo alloy as a third target and the Al target as the first target in the Ar gas at 5×10⁻³ Torr. while maintaining the vacuum state. In this manner, a σ_(w) control layer C comprising a DyFeCoAl film having a film thickness t=100 Å was formed on the M layer.

After the control layer C was formed, Al sputtering was stopped under the same condition as above, and only sputtering of the DyFeCO alloy was performed. In this manner, a W layer comprising a Dy₂₈ Fe₃₆ Co₃₆ perpendicularly magnetizable magnetic film having a film thickness t₂ =400 Å was formed.

Finally, a 1,000-Å thick aluminum nitride film (second protection layer R) was formed on the W layer following the same procedures as those for the first protection layer R.

In this manner, an over-write capable magnetooptical recording medium was obtained. FIG. 1 shows a section of this medium. Both the M and W layers have almost the same groove depth h as that of the groove of the groove material.

Evaluation Test

A magnetooptical recording/reproduction apparatus, which comprised a permanent magnet for applying an initial field Hini.=2 kOe in an "A direction" ↑, and a permanent magnet for applying a bias field Hb=300 Oe in a "non-A direction" ↓, was used. The medium was rotated at a constant linear velocity of 11 m/sec, and the medium was irradiated with a laser beam having a wavelength of 830 nm to record first reference information. The first reference information is a signal having a duty ratio=30% and a frequency=4.0 MHz. The laser beam intensity was set to:

At high level: P_(H) =7.0 mW (on disk)

At low level: P_(L) =3.5 mW (on disk)

The laser beam was pulse-modulated between these two levels.

The first reference information recorded in this manner was reproduced, and a C/N ratio was measured.

Information to be recorded was changed to a signal having a duty ratio=30% and a frequency=7.5 MHz (second reference information). The second reference information was similarly recorded on a region of the medium where the first reference information was recorded. In other words, an over-write operation was performed.

The recorded information was reproduced using a laser beam of 1 mW (on disk), and a C/N ratio was measured.

The above-mentioned evaluation test was conducted for all the media having different groove depths. As a result, the C/N ratio of the first reference information was about 49 dB in all the media. However, the C/N ratio of the second reference information was decreased when the depth exceeded 800 Å, as shown in FIG. 19.

As described above, according to the present invention, when the groove depth is set to be 800 Å or less, a decrease in C/N ratio can be avoided. Note that the groove need not always have a shape shown in FIG. 17. For example, a V-shaped groove may be formed. 

What is claimed is:
 1. An over-write capable magnetooptical recording medium, which includes a substrate having grooves spirally or concentrically formed on a surface thereof; a memory layer consisting of perpendicularly magnetizable magnetic film; and a writing layer consisting of perpendicularly magnetizable magnetic film, these two layers being stacked on said substrate and exchange-coupled, a direction of magnetization of only the writing layer being initially oriented in a predetermined direction, before recording, without changing a direction of magnetization of the memory layer, said medium being capable of over-write recording of different kinds of data by raising the temperature of said medium to different temperature levels, respectively, characterized in that a depth of each of said grooves falls within a range between a minimum depth sufficient for groove tracking and a maximum depth of 800 Å.
 2. A medium according to claim 1, wherein the depth of each of said grooves falls within a range between 300 Å and 800 Å.
 3. A medium according to claim 1, wherein a total film thickness of the memory layer and the writing layer falls within a range between 500 Å and 3,000 Å.
 4. A medium according to claim 3, wherein the total film thickness falls within a range between 500 Å and 900 Å. 